An electronic device (e.g., a diode) is provided that includes a substrate and a patterned layer of superconducting material disposed over the substrate. The patterned layer forms a first electrode, a second electrode, and a loop coupling the first electrode with the second electrode by a first channel and a second channel. The first channel and the second channel have different minimum widths. For a range of current magnitudes, when a magnetic field is applied to the patterned layer of superconducting material, the conductance from the first electrode to the second electrode is greater than the conductance from the second electrode to the first electrode.

An electronic device (e.g., a diode) is provided that includes a substrate and a patterned layer of superconducting material disposed over the substrate. The patterned layer forms a first electrode, a second electrode, and a loop coupling the first electrode with the second electrode by a first channel and a second channel. The first channel and the second channel have different minimum widths. For a range of current magnitudes, when a magnetic field is applied to the patterned layer of superconducting material, the conductance from the first electrode to the second electrode is greater than the conductance from the second electrode to the first electrode.

A yield in a separation process is improved. A separation apparatus which enables easy separation in a large-area substrate is provided. The separation apparatus has a function of dividing a process member into a first member and a second member and includes a support body supply unit, a support body hold unit, a transfer mechanism, a direction changing mechanism, and a structure body. The structure body bonds a support body to a surface of the first member. When at least part of the process member is located between the direction changing mechanism and the structure body or the pressure applying mechanism, the shortest distance between the direction changing mechanism and a first plane including the surface of the first member is longer than the shortest distance between the first plane and the structure body or the pressure applying mechanism.

A process for making a device comprising a thin functional substrate comprising bonding the functional substrate to a carrier substrate, forming functional components on the functional subsrate, and debonding the functional substrate from the carrier substrate by applying ultrasonic wave to the bonding interface. The application of ultrasonic wave aids the debonding step by reducing the tensile stress the functional substrate may experience.

A technique is described in which a transistor formed using an oxide semiconductor film, a transistor formed using a polysilicon film, a transistor formed using an amorphous silicon film or the like, a transistor formed using an organic semiconductor film, a light-emitting element, or a passive element is separated from a glass substrate by light or heat. An oxide layer is formed over a light-transmitting substrate, a metal layer is selectively formed over the oxide layer, a resin layer is formed over the metal layer, an element layer is formed over the resin layer, a flexible film is fixed to the element layer, the resin layer and the metal layer are irradiated with light through the light-transmitting substrate, the light-transmitting substrate is separated, and a bottom surface of the metal layer is made bare.

A peeling method of one embodiment of the present invention includes a first step of forming a first insulating layer over a substrate; a second step of forming a second insulating layer over the first insulating layer; a third step of forming a peeling layer over the second insulating layer; a fourth step of performing plasma treatment on a surface of the peeling layer; a fifth step of forming a third insulating layer over the peeling layer; a sixth step of performing heat treatment; and a seventh step of separating the peeling layer and the third insulating layer from each other. The first insulating layer and the third insulating layer each have a function of blocking hydrogen and for example, include a silicon nitride film or the like. The second insulating layer has a function of releasing hydrogen by heating and for example, includes a silicon oxide film.

An electronic device (e.g., a diode) is provided that includes a substrate and a patterned layer of superconducting material disposed over the substrate. The patterned layer forms a first electrode, a second electrode, and a loop coupling the first electrode with the second electrode by a first channel and a second channel. The first channel and the second channel have different minimum widths. For a range of current magnitudes, when a magnetic field is applied to the patterned layer of superconducting material, the conductance from the first electrode to the second electrode is greater than the conductance from the second electrode to the first electrode.

The present application relates to a method for making semiconductor packages. The method for making semiconductor packages comprises forming a semiconductor package array, the semiconductor package array having at its first side a interconnect encasing layer; attaching an adhesive tape onto the interconnect encasing layer, wherein the adhesive layer has an adhesive layer and a base film; removing, by a laser beam, the base film of the adhesive tape at a predetermined ablation region; and singulating the semiconductor package array along the predetermined ablation regions to separate the semiconductor package array into a plurality of semiconductor packages.

The described method enables removal of any flexible material from a temporary carrier for transfer to another surface. In particular, a semiconductor wafer is commonly held by a temporary adhesive to a carrier substrate for support during a variety of processing steps, including thinning of the semiconductor device layer. Subsequent to processing, the described method attaches the ultra-thin device layer to a roll of tape for removal from the temporary adhesive, followed by transfer to a demount roller, which then releases it onto a desired permanent surface. Utilizing the flexible nature of the ultra-thin device layer, the sequence of rollers is able to peel it from the temporary adhesive without any need for laser release processing or chemical adhesive removal while maintaining the thinned wafer in a planar form during processing. This transfer supports operations that include a change of orientation, such as from face up to face down.

A semiconductor packaging apparatus and methods of manufacturing semiconductor devices using the same. The semiconductor packaging apparatus includes a process unit, and a controller associated with the process unit. The process unit includes a bonding part that bonds a semiconductor substrate and a carrier substrate to each other to form a bonded substrate, a cooling part that cools the bonded substrate, and a detection part in the cooling part and configured to detect a defect of the bonded substrate. The controller is configured to control the process unit using data obtained from the detection part.